Chapter 3 TENSION MEMBER DESIGN -...
Transcript of Chapter 3 TENSION MEMBER DESIGN -...
Chapter 3 TENSION MEMBER DESIGN
3.1 INTRODUCTORY CONCEPTS
Tension member are structural elements that subjected to axial tensile forces.
Generally they are used in
• Truss members
• Bracing for building and bridges
• Cables such as
§ Suspended roof systems
§ Suspension
§ Bridges
Any cross sectional configuration may be used, circular rod and rolled angle shapes are frequently used.
Other shapes may be used when large load must be resisted.
The stress in an axially loaded tension member is given by Equation (3.1)
Apf = (3.1)
where, P is the magnitude of load, and
A is the cross-sectional area normal to the load.
The stress in a tension member is uniform throughout the cross-section except
• near the point of application of load, and • at the cross-section with holes for bolts.
The cross sectional area will be reduced by amount equal to the area removed by holes. Tension members are frequently connected at their ends with bolts as shown in example:
Consider an 8 x ½ in. bar connected to a gusset plate and loaded in tension as shown
below in Figure 3.1
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Figure 3.1 Example of tension member
Area of bar at section a - a = 8 x ½ = 4 in2 Area of bar at section b - b = (8 - 2 x 7/8 ) x ½ = 3.13 in2
The unreduced area of the member is called its gross area = Ag
The reduced area of the member is called its net area = An
The typical design problem is to select a member with sufficient cross sectional area
Factored load < factored strength
3.2 DESIGN STRENGTH
A tension member can fail by reaching one of two limit states:
(1) excessive deformation; or (2) fracture
Excessive deformation can occur due to the yielding of the gross section (for example section
a-a from Figure 3.1) along the length of the member.
To prevent excessive deformation, the stress at the gross sectional area must be smaller than yielding
stress (f < Fy)
Fracture of the net section can occur if the stress at the net section (for example section b-b in
Figure 3.1) reaches the ultimate stress Fu.
To prevent Fracture, the stress at the net sectional area must be smaller than ultimate stress (f < Fu).
In each case the stress P/A must be less than a limiting stress F or:
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P/A < F
P < F*A
Where P is the applied factored load and
F*A is the strength load.
The nominal strength in yielding is
Pn = Fy * Ag
And the nominal strength in fracture is
Pn = Fu* Ae
Where Ae is the effective net area.
Ae ≤ An
The resistance factor Φ = Φt is smaller for fracture than for yielding reflecting the more serious nature
of reaching the limit state of fracture
For yielding Φt =0.90
For fracture Φt =0.75
So the equation
∑ γi Qi ≤ Φ Rn
Can be written for tension member as:
∑ γi Qi ≤ Φt Rn or
Pu ≤ Φt Pn
Where Pu is the governing combination of factored loads.
Because there are two limit states, both of the following conditions must be satisfied:
Pu ≤ 0.90 Fy Ag
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Pu ≤ 0.75 Fu Ae
The smaller of these is the design strength of the member.
Important notes
Note 1:
Why is fracture (& not yielding) the relevant limit state at the net section? Yielding will occur first in
the net section. However, the deformations induced by yielding will be localized around the net
section. These localized deformations will not cause excessive deformations in the complete tension
member. Hence, yielding at the net section will not be a failure limit state.
Note 2:
What is the amount of area to be deducted from the gross area to account for the presence of bolt-holes?
The nominal diameter of the hole is equal to the bolt diameter + 1/16 in.
However, the bolt-hole fabrication process damages additional material around the hole diameter.
Assume that the material damage extends 1/16 in. around the hole diameter.
Therefore, for calculating the net section area, assume that the gross area is reduced by a
hole diameter equal to the nominal hole-diameter + 1/16 in.
Example 3.1
A 5 x ½ bar of A572 Gr. 50 steel is used as a tension member. It is connected to a gusset plate with six 7/8 in. diameter bolts as shown in below. Assume that the effective net area Ae equals the actual net area An and compute the tensile design strength of the member.
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Solution • Gross section area = Ag = 5 x ½ = 2.5 in2 • Net section area (An)
- Bolt diameter = db = 7/8 in.
- Nominal hole diameter = dh = 7/8 + 1/16 in. = 15/16 in.
- Hole diameter for calculating net area = 15/16 + 1/16 in. = 1 in.
- Net section area = An = (5 - 2 x (1)) x ½ = 1.5 in2 • Gross yielding design strength = φt Pn = φt Fy Ag
- Gross yielding design strength = 0.9 x 50 ksi x 2.5 in2 = 112.5 kips • Fracture design strength = φt Pn = φt Fu Ae
- Assume Ae = An (only for this problem)
- Fracture design strength = 0.75 x 65 ksi x 1.5 in2 = 73.125 kips
• Design strength of the member in tension = smaller of 73.125 kips and 112.5 kips
-Therefore, design strength = 73.125 kips (net section fracture controls).
Example 3.2 A single angle tension member, L 4 x 4 x 3/8 in. made from A36 steel is connected to a
gusset plate with 5/8 in. diameter bolts, as shown in Figure below. The service loads are
35 kips dead load and 15 kips live load. Determine the adequacy of this member using
AISC specification. Assume that the effective net area is 85% of the computed net area.
(Calculating the effective net area will be taught in the next section).
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• Gross area of angle = Ag = 2.86 in2 (from Manual)
• Net section area = An
- Bolt diameter = 5/8 in.
- Nominal hole diameter = 5/8 + 1/16 = 11/16 in.
- Hole diameter for calculating net area = 11/16 + 1/16 = 3/4 in.
- Net section area = Ag - (3/4) x 3/8 = 2.86 - 3/4 x 3/8 = 2.579 in2
• Effective net area = Ae = 0.85 x 2.579 in2 = 2.192 in2 • Gross yielding design strength = φt Ag Fy = 0.9 x 2.86 in2 x 36 ksi = 92.664 kips • Net section fracture = φt Ae Fu = 0.75 x 2.192 in2 x 58 ksi = 95.352 kips
• Design strength = 92.664 kips (gross yielding governs) • Ultimate (design) load acting for the tension member = Pu
- The ultimate (design) load can be calculated using factored load combinations given by
the AISC manual equations.
- According to these equations, two loading combinations are important for this problem.
These are: (1) 1.4 D; and
(2) 1.2 D + 1.6 L
- The corresponding ultimate (design) loads are:
1.4 x (D) = 1.4 (35) = 49 kips
1.2 (D) + 1.6 (L) = 66 kips (controls)
- The ultimate design load for the member is 66 kips, where the factored dead + live loading
condition controls. • Compare the design strength with the ultimate design load The design strength of the member (92.664 kips) is greater than the ultimate design load (66 kips).
φt Pn (92.664 kips) > Pu (66 kips)
• The L 4 x 4 x 3/8 in. made from A36 steel is adequate for carrying the factored loads.
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3.3 EFFECTIVE NET AREA (Ae)
• The connection has a significant influence on the performance of a tension member. A
connection almost always weakens the member, and a measure of its influence is called
joint efficiency.
• Joint efficiency is a function of:
material ductility;
fastener spacing;
stress concentration at holes;
fabrication procedure; and
shear lag.
• All factors contribute to reducing the effectiveness but shear lag is the most important.
• Shear lag occurs when the tension force is not transferred simultaneously to all elements of
the cross-section. This will occur when some elements of the cross-section are not
connected.
For example, see Figure 3.2 below, where only one leg of an angle is bolted to the gusset plate.
Figure 3.2 Single angle with bolted connection to only one leg
• A consequence of this partial connection is that the connected element
becomes overloaded and the unconnected part is not fully stressed.
• Lengthening the connection region will reduce this effect
• Munse and Chesson (1963) suggests that shear lag can be accounted for
by using a reduced or effective net area Ae.
• Shear lag affects both bolted and welded connections. Therefore, the
effective net area concept applied to both types of connections.
- For bolted connection, the effective net area is Ae = U An
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- For welded connection, the effective net area is Ae = U Ag
• Where, the reduction factor U is given by:
• Where, x is the distance from the centroid of the connected area to the plane of the
connection, and L is the length of the connection.
• If the member has two symmetrically located planes of connection, x is measured from the
centroid of the nearest one - half of the area.
• Additional approaches for calculating x for different connection types are shown in Figure
3.7 page 41
• The distance L is defined as the length of the connection in the direction of load.
• For bolted connections, L is measured from the center of the bolt at one end to the center of
the bolt at the other end.
• For welded connections, it is measured from one end of the connection to other.
• If there are weld segments of different length in the direction of load, L is the length of the
longest segment.
• Example Figure 3.8 for calculating L are given on page 42.
• The AISC manual also gives values of U that can be used instead of calculating x /L.
• They are based on average values of x /L for various bolted connections.
• For W, M, and S shapes with width-to-depth ratio of at least 2/3 and for Tee shapes cut
from them, if the connection is through the flanges with at least three fasteners per line in
the direction of applied load ……………..……………………………..…...U = 0.90
• For all other shapes with at least three fasteners per line …………………... U = 0.85
• For all members with only two fasteners per line …………………………… U = 0.75
• For better idea, see Figure 3.9 on page 43 of the Segui text-book.
• These values are acceptable but not the best estimate of U
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• If used in the exam or homework, full points for calculating U will not be given.
Special cases for welded connections
If some elements of the cross-section are not connected, then Ae will be less than An
-For a rectangular bar or plate Ae will be equal to An
-However, if the connection is by longitudinal welds at the ends as shown in the
figure below, then Ae = UAg
Where, U = 1.0 for L ≥ w U = 0.87 for 1.5 w ≤ L < 2 w U = 0.75 for w ≤ L < 1.5 w
L = length of the pair of welds ≥ w
w = distance between the welds or width of plate/bar
AISC Specification B3 gives another special case for welded connections.
For any member connected by transverse welds alone,
Ae = area of the connected element of the cross-section
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Example 3.3
Determine the effective net area and the corresponding design strength for the single angle tension
member of Example 3.2. The tension member is an L 4 x 4 x 3/8 in. made from A36 steel. It is
connected to a gusset plate with 5/8 in. diameter bolts, as shown in Figure below. The spacing between
the bolts is 3 in. center-to-center. Compare your results with those obtained for Example 3.2.
• Gross area of angle = Ag = 2.86 in2 (from Manual) • Net section area = An
- Bolt diameter = 5/8 in.
- Hole diameter for calculating net area = 5/8 + 1/8 = 3/4 in.
- Net section area = Ag - (3/4) x 3/8
= 2.86 - 3/4 x 3/8 = 2.579 in2
• x is the distance from the centroid of the area connected to the plane of connection
- For this case x is equal to the distance of centroid of the angle from the edge.
- This value is given in the AISC manual.
- x = 1.13 in. • L is the length of the connection, which for this case will be equal to
2 x 3.0 in.
- L = 6.0 in.
• U = 1- (1.13/6.0) = 0.8116
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• Effective net area = Ae = 0.8116 x 2.579 in2 = 2.093 in2
• Gross yielding design strength = φt Ag Fy = 0.9 x 2.86 in2 x 36 ksi = 92.664 kips • Net section fracture = φt Ae Fu = 0.75 x 2.093 in2 x 58 ksi = 91.045 kips • Design strength = 91.045 kips (net section fracture governs) • In Example 3.2
- Factored load = Pu = 66.0 kips
- Design strength = φt Pn = 92.66 kips (gross section yielding governs)
- Net section fracture strength = φt Pn = 95.352 kips (assuming Ae = 0.85) • Comparing Examples 3.2 and 3.3
- Calculated value of U (0.8166) is less than the assumed value (0.85)
- The assumed value was unconservative.
- It is preferred that the U value be specifically calculated for the section.
- After including the calculated value of U, net section fracture governs the
design strength, but the member is still adequate from a design standpoint
Example 3.4 Determine the design strength of an ASTM A992 W8 x 24 with four lines if ¾ in.
diameter bolts in standard holes, two per flange, as shown in the Figure below. Assume the holes are
located at the member end and the connection length is 9.0 in.
Solution: • For ASTM A992 material: Fy = 50 ksi; and Fu = 65 ksi • For the W8 x 24 section:
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- Ag = 7.08 in2 d = 7.93 in.
- tw = 0.285 in. bf = 6.5 in. - tf = 0.4 in. ry = 1.61 in.
• Net section fracture strength = φt Ae Fu = 0.75 x Ae x 65
- Ae = U An - for bolted connection
- An = Ag - (no. of holes) x (diameter of hole) x (thickness of flange)
An = 7.08 - 4 x (diameter of bolt (3/4)+ 1/8) x 0.4 = 5.68 in2
• What is x for this situation? x is the distance from the edge of the flange to the
centroid of the half (T) section.
• x can be obtained from the dimension tables for Tee section WT 4 x 12. of the
AISC manual:
• x = 0.695 in
• U= 1- (0.695/9.0) = 0.923
• But, U ≤ 0.90. Therefore, assume U = 0.90
• Gross yielding design strength = φt Ag Fy = 0.90 x 7.08 x 50 = 319 kips
• Net section fracture strength = φt Ae Fu = 0.75 x 0.9 x 5.68 x 65 = 249.2 kips • The design strength of the member is controlled by net section fracture = 249.2 kips
Example 3.5 Consider the welded single angle L 6x 6 x ½ tension member made from
A36 steel shown below. Calculate the tension design strength.
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Solution • Ag = 5.00 in2
• An = 5.00 in2 - because it is a welded connection • Ae = U An
- x = 1.68 in. for this welded connection
- L = 6.0 in. for this welded connection
• U = 1- (1.68/6.0) = 0.72
• Gross yielding design strength = φt Fy Ag = 0.9 x 36 x 5.00 = 162 kips • Net section fracture strength = φt Fu Ae = 0.75 x 58 x 0.72 x 5.00 = 156.6 kips
• Design strength = 156.6 kips (net section fracture governs)
3.4 STAGGERED FASTENERS (BOLTS)
For a bolted tension member, A maximum net area can be achieved if the bolts are placed in a single line.
The connecting bolts can be staggered for several reasons:
(1) To get more capacity by increasing the effective net area
(2) To achieve a smaller connection length
(3) To fit the geometry of the tension connection itself.
For a tension member with staggered bolt holes (see example Figure), the relationship f = P/A does not apply and
the stresses are a combination of tensile and shearing stresses on the inclined portion b-c.
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Net section fracture can occur along any zig-zag or straight line. For example, fracture can occur
along the inclined path a-b-c-d in the figure above. However, all possibilities must be examined.
Empirical methods have been developed to calculate the net section fracture strength.
According to AISC Specification B2
where, d is the diameter of hole to be deducted (dh + 1/16, or db + 1/8)
s2/4g is added for each gage space in the chain being considered
s is the longitudinal spacing (pitch) of the bolt holes in the direction of loading
g is the transverse spacing (gage) of the bolt holes perpendicular to loading dir.
net area (An) = net width x plate thickness
effective net area (Ae) = U An where U = 1- x /L
net fracture design strength = φt Ae Fu (φt = 0.75)
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EXAMPLE 3.6
Compute the smallest net area for the plate shown below: The holes are for 1 in. diameter bolts.
• The effective hole diameter is 1 + 1/8 = 1.125 in.
• For line a-b-d-e
wn = 16.0 - 2 (1.125) = 13.75 in.
• For line a-b-c-d-e
wn = 16.0 - 3 (1.125) + 2 x 32/ (4 x 5) = 13.52 in.
• The line a-b-c-d-e governs:
An = t wn = 0.75 (13.52) = 10.14 in2
Note:
Each fastener resists an equal share of the load
Therefore different potential failure lines may be subjected to different loads.
For example, line a-b-c-d-e must resist the full load, whereas i-j-f-h will be subjected to
8/11of the applied load. The reason is that 3/11 of the load is transferred from the
member before i-j-f-h received any load.
Staggered bolts in angles:
If staggered lines of bolts are present in both legs of an angle, then the net area is found by first
unfolding the angle to obtain an equivalent plate. This plate is then analyzed like shown above.
The unfolding is done at the middle surface to obtain a plate with gross width equal to the sum of the
leg lengths minus the angle thickness.
AISC Specification B2 says that any gage line crossing the heel of the angle should be reduced by an
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amount equal to the angle thickness.
See Figure below. For this situation, the distance g will be = 3 + 2 - ½ in.
Example 3.7
Find the tensile design strength of the angle shown in the Figure. A36 steel is used and holes are for 7/8
in. diameter bolts.
Solution:
Effective hole diameter = 7/8 + 1/8 = 1 in.
For line abdf the net width is:
Wn = 13.5 – 2*1 = 11.5 in2
For line abceg the net width is:
Wn = 13.5 – 3*1 + ((1.5)2/4*2.5) = 10.73 in2
Because 1/10 of the load has been transferred from the member by the fastener at d, this potential failure line must resist only 9/10 of the load. Therefore, the net width of 10.73 should be multiplied by 10/9 to obtain a net width that can be compared with those lines that resist the full load. Use Wn = 10.73 * 10/9 = 11.92 in.
For line abcdeg,
gcd = 3 + 2.25 – 0.5 = 4.75 in
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Wn = 13.5 – 4*1 + ((1.5)2/4*2.5) + ((1.5)2/4*4.75) + ((1.5)2/4*3) = 10.03 in2
The last case control
An = t * Wn = 0.50 * 10.03 = 5.015 in2
Both legs of the angle are connected, so
Ae = An = 5.015 in2
The design strength load based on fracture is
Pu = 0.75 * 58 * 5.015 = 218 kips
The design strength load based on yielding is
Pu = 0.90 * 36 * 6.75 = 219 kips.
Fracture control the design strength = 218 kips.
Note:
Another equation can be used to determine area net directly:
An = Ag - ∑ t * (d or D)
Where D = d – (s2/4g)
See examples in pages 49,50 and 51.
3.5 BLOCK SHEAR
For some connection configurations, the tension member can fail due to ‘tear-out’ of
material at the connected end. This is called block shear.
For example, the single angle tension member connected as shown in the Figure
below is susceptible to the phenomenon of block shear.
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Block shear failure of single angle tension member
For the case shown above, shear failure will occur along the longitudinal section a-b
and tension failure will occur along the transverse section b-c
AISC Specification (SPEC) Chapter D on tension members does not cover block
shear failure explicitly. But, it directs the engineer to the
Chapter (Connection, Joints, and Fasteners), Section J4.3
Block shear strength is determined as the sum of the shear strength on a failure path and the tensile
strength on a perpendicular segment.
Block shear strength = net section fracture strength on shear path + gross yielding strength on the
tension path
OR
Block shear strength = gross yielding strength of the shear path + net section fracture strength of the
tension path
Which of the two calculations above governs?
When Fu Ant ≥ 0.6Fu Anv; φt Rn = φ (0.6 Fy Agv + Fu Ant) ≤ φ (0.6 FuAnv + Fu Ant)
When Fu Ant < 0.6Fu Anv; φt Rn = φ (0.6 Fu Anv + Fy Agt) ≤ φ (0.6 FuAnv + Fu Ant)
Where, φ = 0.75
Agv = gross area subject to shear
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Agt = gross area subject to tension
Anv = net area subject to shear
Ant = net area subject to tension
EXAMPLE 3.8
Calculate the block shear strength of the single angle tension member considered in Examples 3.2 and
3.3. The single angle L 4 x 4 x 3/8 made from A36 steel is connected to the gusset plate with 5/8 in.
diameter bolts as shown below. The bolt spacing is 3 in. center-to-center and the edge distances are
1.5 in and 2.0 in as shown in the Figure below. Compare your results with those obtained in Example
3.2 and 3.3
Step I. Assume a block shear path and calculate the required areas
Agt = gross tension area = 2.0 x 3/8 = 0.75 in2
Ant = net tension area = 0.75 - 0.5 x (5/8 + 1/8) x 3/8 = 0.609 in2
Agv = gross shear area = (3.0 + 3.0 +1.5) x 3/8 = 2.813 in2
Anv = net tension area = 2.813 - 2.5 x (5/8 + 1/8) x 3/8 = 2.109 in2
Step II. Calculate which equation governs
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- 0.6 Fu Anv = 0.6 x 58 x 2.109 = 73.393 kips
- Fu Ant = 58 x 0.609 = 35.322 kips
- 0.6 Fu Anv > Fu Ant
- Therefore, equation with fracture of shear path governs
Step III. Calculate block shear strength - φt Rn = 0.75 (0.6 Fu Anv + Fy Agt) - φt Rn = 0.75 (73.393 + 36 x 0.75) = 75.294 kips
Compare with results from previous examples
Example 3.2:
Ultimate factored load = Pu = 66 kips
Gross yielding design strength = φt Pn = 92.664 kips
Assume Ae = 0.85 An
Net section fracture strength = 95.352 kips
Design strength = 92.664 kips (gross yielding governs)
Example 3.3
Calculate Ae = 0.8166 An
Net section fracture strength = 91.045 kips
Design strength = 91.045 kips (net section fracture governs)
Member is still adequate to carry the factored load (Pu) = 66 kips
Example 3.8
Block shear fracture strength = 75.294 kips
Design strength = 75.294 kips (block shear fracture governs)
Member is still adequate to carry the factored load (Pu) = 66 kips
Bottom line:
Any of the three limit states (gross yielding, net section fracture, or block shear failure) can govern.
The design strength for all three limit states has to be calculated.
The member design strength will be the smallest of the three calculated values
The member design strength must be greater than the ultimate factored design load in tension.
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Practice Example Determine the design tension strength for a single channel C15 x 50 connected to a 0.5 in. thick
gusset plate as shown in Figure. Assume that the holes are for 3/4 in. diameter bolts and that the plate
is made from structural steel with yield stress (Fy) equal to 50 ksi and ultimate stress (Fu) equal to 65
ksi.
▪ Limit state of yielding due to tension:
▪ Limit state of fracture due to tension
▪ Limit state of block shear rupture:
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Block shear rupture is the critical limit state and the design tension strength is 464kips.
4.6 Design of tension members
The design of a tension member involves finding the lightest steel section (angle, wideflange, or
channel section) with design strength (φPn) greater than or equal to the maximum factored design
tension load (Pu) acting on it.
φ Pn ≥ Pu
Pu is determined by structural analysis for factored load combinations
φ Pn is the design strength based on the gross section yielding, net section fracture, and block
shear rupture limit states.
For gross yielding limit state, φPn = 0.9 x Ag x Fy
Therefore 09 x Ag x Fy ≥ Pu
Therefore Ag ≥ Pu/(0.9 Fy)
For net section fracture limit state, φPn = 0.75 x Ae x Fu
Therefore, 0.75 x Ae x Fu ≥ Pu
Therefore, Ae ≥ Pu/(0.75Fu)
But, Ae = U An
Where, U and An depend on the end connection
Thus, designing the tension member goes hand-in-hand with designing the end connection, which we
have not covered so far.
Therefore, for this chapter of the course, the end connection details will be given in the examples and
problems
The AISC manual tabulates the tension design strength of standard steel sections Include:
Wide flange shapes, angles, tee sections, and double angle sections
The gross yielding design strength and the net section fracture strength of each section is
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tabulated.
This provides a great starting point for selecting a section.
There is one serious limitation
• The net section fracture strength is tabulated for an assumed value of U = 0.75,
obviously because the precise connection details are not known
• For all W, Tee, angle and double-angle sections, Ae is assumed to be = 0.75 Ag
• The engineer can first select the tension member based on the tabulated gross
yielding and net section fracture strengths, and then check the net section fracture
strength and the block shear strength using the actual connection details.
Additionally for each shape the manual tells the value of Ae below which net section fracture will
control:
• Thus, for W shapes net section fracture will control if Ae < 0.923 Ag
• For single angles, net section fracture will control if Ae < 0.745 Ag
• For Tee shapes, net section fracture will control if Ae < 0.923
• For double angle shapes, net section fracture will control if Ae < 0.745 Ag
Slenderness limits
Tension member slenderness l/r must preferably be limited to 300 as per LRFD specification B7
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Example 3.10
Design a member to carry a factored maximum tension load of 100 kips. Assume that the member is a
wide flange connected through the flanges using eight in. diameter bolts in two rows of four each as
shown in the figure below. The center-to-center distance of the bolts in the direction of loading is 4 in.
The edge distances are 1.5 in. and 2.0in. as shown in the figure below. Steel material is A992
Solution Required Ag = Pu/(0.90Fy) = 100/(0.90*50) = 2.22 in2
Required Ae = Pu/(075Fu) = 100/(075*65) = 2.051 in2
Try W8x10 with Ag = 2.96 in2, tf = 0.205 in.
An = 2.96 - 4 (3/4 + 1/8) x 0.205 = 2.24 in2
The connection is only through the flanges. Therefore, the shear lag factor U will be the distance from
the top of the flange to the centroid of a WT 4 x 5
x = 0.953
U = 1- x /L = 1 - 0.953 / 4 = 0.76
Ae = 0.76 An = 0.76 x 2.24 = 1.70 in2
Unacceptable because Ae = 2.051 in2; REDESIGN required
Go to the section dimension of the AISC manual. Select next highest section.
For W 8 x 13, tf = 0.255 in
From Manual W8 x 13 has Ag = 3.84 in2
An = 3.84 - 4 (3/4 + 1/8) x 0.255 = 2.95 in2
From dimensions of WT4 x 6.5, x = 1.03 in.
Therefore, U = 1- x /L = 1-1.03/4 = 0.74
Therefore, Ae = U An = 0.74 x 2.95 = 2.19 in2 ≥ 2.051 in2
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Therefore, net section fracture strength = 0.75 x 65 x 2.19 = 106.7 kips
Therefor, net section yielding strength = 0.90 x 50 x 3.84 = 172.8 kips
Which both are greater than 100 kips (design load). Therefore, W 8 x 13 is acceptable.
Check the block shear rupture strength
Identify the block shear path
The block shear path is show above. Four blocks will separate from the tension member (two from
each flange) as shown in the figure above.
Agv = [(4+2) x tf ] x 4 = 6 x 0.255 x 4 = 6.12 in2 for four tabs
Anv = {4+2 - 1.5 x (db+1/8)} x tf x 4 = 4.78 in2
Agt = 1.5 x tf x 4 = 1.53 in2
Ant = {1.5 - 0.5 x (db+1/8)}x tf x 4 = 1.084 in2
Identify the governing equation:
FuAnt = 65 x 1.084 = 70.4 kips
0.6FuAnv = 0.6 x 65 x 4.78 = 186.42 kips , which is > FuAnt
Calculate block shear strength
φtRn = 0.75 (0.6FuAnv + FyAgt) = 0.75 (186.42 + 50 x 1.53) = 197.2 kips
Which is greater than Pu = 100 kips. Therefore W8 x 13 is still acceptable
• Summary of solution
Another examples in pages 55, 56, 57 and 58
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